The actin cytoskeleton is a major determinant of the mechanical properties of embryonic cells and tissues. Spatial and temporal modulations of these properties play a major role in cellular transformation and important aspects of cancer such as cell division, polarity and migration.
In embryonic cells, actomyosin forms a cortical reticulated gel that turns over rapidly, is weakly organized, and is composed of a variety of structures, with distinct architectures and dynamics. These structures are nucleated and elongated by different factors, and bind to specific sets of actin-binding proteins that modulate their dynamics. For example, in C. elegans, at least two types of cytoskeletal structures simultaneously coexist in the cell: short, branched actin filaments, nucleated by arp2/3, and long actin filaments/bundles nucleated by formins. Understanding how actin is distributed between these structures is critical to understand the biology and mechanics of the actin cytoskeleton and therefore its role in processes ranging from morphogenesis and cell division to endocytosis and polarization.
We take advantage of high-resolution techniques to tease out the general rules and the critical regulatory elements that control actin dynamics.
On the long term, this project may also improve our understanding of the general mechanisms that underlie the regulation of the actin cytoskeleton machinery, and how deregulations may be responsible for the onset of specific behaviors of the actin cytoskeleton that may eventually result in the development of cancer-like cellular behaviors.